The present disclosure relates to a stabilization system for a marine vessel and, more particularly, to a stabilization system utilizing inflatable bladders for suppressing rolling motion of the marine vessel.
The roll axis of a boat is an imaginary line running horizontally along the length of a boat, through its center of gravity, and parallel to the waterline. Movements about the roll axis of a boat are felt as a rolling motion from side-to-side, i.e., a port-to-starboard tilting motion. These movements about the roll axis are considered troublesome and are one of the most common causes of motion sickness. On very small boats this is experienced immediately when passengers step off the dock onto the boat, as their weight causes a disturbing heel, and then rolling swaying, of the hull. Further, when tied to a dock or in a slip in relatively calm water, wakes from passing boats can cause unexpected and rapid rolling motions, which may cause the boat to hit against the dock.
In order to alleviate the rolling motion, stabilization or suppression devices have been designed to dampen the roll of a boat, but most are directed toward larger ships such as large motor yachts, offshore and commercial vessels and ships used in defense and security. The main reason for the limitations on the use of stabilization devices has been economic reasons. For instance, external fins are widely used roll suppression devices on ships. The fins can be activated by hydraulic or pneumatic mechanisms and respond to the output of motion sensing devices so as to keep the damping effect of the fin lift in phase with the roll velocity of the vessel. Fins are generally effective, however, when the vessel is underway since the passage of water over the fins is necessary in order for them to generate the damping lift.
There is thus a need in the art for a cost efficient stabilization system and method for suppressing the roll motion in smaller marine vessels both while underway and while at anchor.
Pleasure boating in smaller boats, such as ski boats, cuddy cabins, and the like, can be a very enjoyable experience on water bodies such as bays, rivers, lakes, etc., but for individuals sensitive to motion sickness, this is not the case. The unpleasantness of motion sickness is further amplified when a sudden weather system is encountered during an otherwise calm day, bring with it increased swells and whitecaps. Hence, in order to suppress the roll motion encountered in smaller boats, a stabilization system can be attached to the smaller boats to attenuate rotation of the boat hull about the roll axis during normal cruising, in response to heightened sea state, and when at anchor. The stabilization system thus lessens the prospect of motion sickness in individuals prone to the same both on calm days or when sudden weather is confronted.
In one aspect, the disclosure provides a stabilization system for a marine vessel including at least two inflatable bladders configured to be attached to the marine vessel, a gyroscopic sensor configured to sense an angular orientation of the marine vessel, and a controller configured for inflating and deflating the at least two inflatable bladders responsive to the angular orientation sensed by the gyroscopic sensor.
A further aspect of the disclosure provides a marine vessel having at least one hull, a stabilization system for attenuating rotation of the at least one hull about at least one axis of the marine vessel, the stabilization system including at least two inflatable bladders, a gyroscopic unit for sensing rotation of the at least one hull, and a controller in communication with the gyroscopic unit. According to an exemplary embodiment of the disclosure, one of the at least two inflatable bladders is disposed along a first side of the hull and another of the at least two inflatable bladders is disposed along a second side of the hull. The controller is thus configured to inflate or deflate one or more of the at least two inflatable bladders in order to counteract the rotation of the at least one hull sensed by the gyroscopic unit.
A system and method for stabilization of a marine vessel includes providing a marine vessel having a hull with a stabilization system including at least one inflatable bladder on a first side of the hull and at least one inflatable bladder on a second side of the hull, providing a gyroscopic unit for measuring an angular rolling motion of the hull about an axis, the gyroscopic unit communicating the measured angular rolling motion to a controller, and inflating or deflating at least one of the inflatable bladder on the first side and the inflatable bladder on the second side based upon the measured angular rolling motion.
Other systems, methods, features and advantages of the disclosure will be, or will become, apparent to one of ordinary skill in the art upon examination of the following figures and detailed description. It is intended that all such additional systems, methods, features and advantages be included within this description and this summary, be within the scope of the disclosure, and be protected by the following claims.
The disclosure can be better understood with reference to the following drawings and description. The components in the figures are not necessarily to scale, emphasis instead being placed upon illustrating the principles of the disclosure. Moreover, in the figures, like reference numerals designate corresponding parts throughout the different views.
Referring to
As shown in
Referring also to
In the exemplary embodiment of the disclosure, air is supplied to the air control valves 28, 30 from an air tank 26 or other reservoir suitable for holding pressurized air. The air tank 26 is pressurized by a compressor 32, such as an engine driven compressor. If required, a heat exchanger (not shown) may also be provided for cooling the engine driven compressor 32.
In addition to the information provided to the controller 24 by the gyroscopic unit 22, i.e., the non-zero value corresponding to the angular roll of the vessel 12, known information from other navigational components such as wind direction, wind speed, vessel speed, and the like may also be communicated to the controller 24 and utilized in formulation of the appropriate inflation/deflation response for each bladder 18, 20. Further, weather forecasts, sea state conditions, and other information may be communicated to the controller 24 in order to predictively inflate/deflate each bladder based upon the environment expected to be encountered. The inflatable bladders 18, 20 are formed from rubber or other expandable material capable of withstanding the inflation pressure within the bladders 18, 20. The particular material chosen and the thickness of the material will of course depend upon the intended maximum inflation pressure, which is based upon the size, weight and purpose of the marine vessel on which the bladders are being utilized. The bladders 18, 20 should be constructed from a light weight, durable material that can repeatedly expand and contract without failure or fatigue. According to the disclosure herein, the bladders 18, 20 are installed on the vessel 12 by gluing such as with an adhesive, or by ultrasonic welding, or any other type of attachment means that can attach the bladders 18, 20 to the hull 14 without degradation of the bladder material. Alternatively, a pocket made from a mesh or other water permeable material could be attached to the hull of the marine vessel, and the inflatable bladders could be removably retained within the pockets. When properly installed, the inflatable bladders 18, 20 are disposed below or at least partially below the surface of the water line WL. Precise positioning of the inflatable bladders 18, 20 relative to the water line, i.e., positioning more or less of the bladder on the freeboard of the hull above the water line, is not required and will vary based upon the size and weight of the marine vessel 12.
Referring also to
Further, while stabilization 10, 10′ is described above as being employed on monohull marine vessels and other boats having more than one hull, such as catamarans and the like, stabilization system 10, 10′ could also be employed on an inflatable marine vessel 38 such as shown in
While various embodiments of the disclosure have been described, the description is intended to be exemplary, rather than limiting and it will be apparent to those of ordinary skill in the art that many more embodiments and implementations are possible that are within the scope of the disclosure. Accordingly, the disclosure is not to be restricted except in light of the attached claims and their equivalents. Also, various modifications and changes may be made within the scope of the attached claims.
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Number | Date | Country |
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Espacenet Machine Translation of CN Patent 204726636 U, Issued Oct. 28, 2015. |
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Number | Date | Country | |
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20210291942 A1 | Sep 2021 | US |